1. Uremia-related vascular calcification: More than apatite deposition
S.C. Verberckmoes, V. Persy, G.J. Behets, E. Neven, A. Hufkens, H. Zebger-Gong, D. Müller, D. Haffner, U. Querfeld, S. Bohic, M.E. De Broe, P.C. D'Haese 
Kidney International 
Volume 71, Issue 4, Pages (February 2007)
DOI: /sj.ki
Copyright © 2007 International Society of Nephrology Terms and Conditions

2. Figure 1
Mineral identification in the calcified aorta of uremic rats. (a) Based on a video microscopic image of the aortic wall a region of interest was defined which was further investigated by means of X-ray fluorescence mapping for the presence of (b) phosphorus and (c) calcium (Bar=50μm). By performing several line scans through the region of interest X-ray diffraction patterns were recorded and averaged over the line scan. (d) After the circular integration of the recorded diffraction patterns (see Materials and Methods) the mineral phase of the investigated aortic region could be identified either as (i) amorphous precipitate, (ii) apatite, or (iii) a mixture of apatite and whitlockite. In some aortic regions the calcium phosphate was present as an amorphous precipitate whereas in others the mineral could be identified as calcium apatite (black arrow heads). Only samples originating from the vitamin D-treated renal failure animals next to apatite (black arrow heads) also an additional mineral phase was found, identified as whitlockite (open arrow heads).
Kidney International  , DOI: ( /sj.ki )
Copyright © 2007 International Society of Nephrology Terms and Conditions

3. Figure 2
Calcium X-ray fluorescence and X-ray diffraction patterns of the deposited mineral in the aorta of uremic rats. Representation of the ultrastructural spatial heterogeneity of the identified mineral phases: (a) apatite and (b) apatite and whitlockite. These mineral phases were further investigated by performing line scans with a 10μm step size through the vessel wall. During this line scan patterns both X-ray fluorescence for calcium (upper panel) and diffraction (lower panel) were recorded for each 10μm step. The integrated diffraction pattern for each point of the line scan is presented in the lower panel as percentage of maximum peak intensity in a 2D-height-field. The gray shaded regions in the calcium signal in the upper panel for (a) apatite and (b) apatite and whitlockite represent the scan points where no mineral phase but amorphous calcium phosphate phase was found. The white dotted line through the diffraction height-field marks the position of the detailed diffraction patterns shown left (whitlockite) and right (apatite). The white arrow heads indicate the diffraction peak positions typical for whitlockite whereas the black arrow heads indicate the apatite peaks. These data also show that the whitlockite mineral phase is not homogeneously distributed through the aortic calcification.
Kidney International  , DOI: ( /sj.ki )
Copyright © 2007 International Society of Nephrology Terms and Conditions

4. Figure 3
Magnesium/calcium ratios of the calcified aortas in both models. Statistical evaluation of the data with a Mann–Whitney test showed a significantly (P<0.05) higher magnesium/calcium ratio in the aortas of vitamin D-treated 5/6 nephrectomized rats vs adenine-treated animals receiving a high-phosphate diet.
Kidney International  , DOI: ( /sj.ki )
Copyright © 2007 International Society of Nephrology Terms and Conditions